US1353205A

US1353205A - Rotary internal-combustion engine

Info

Publication number: US1353205A
Application number: US276012A
Authority: US
Inventors: William H Woodward
Original assignee: GEORGE M POTTER
Current assignee: GEORGE M POTTER
Priority date: 1919-02-10
Filing date: 1919-02-10
Publication date: 1920-09-21
Anticipated expiration: 1937-09-21

Description

Y W. H. WOODWARD. ROTARY INTERNAL COMBUSTION ENGINE.

Patented Sept, 21,1920.

6 SHEETSSHEET I.

APPLICATION HLED FEB. 10. 1919.

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W. H. WOODWARD.

ROTARY INTERNAL COMBUSTION ENGINE:

APPLICATION men FEB. I0. 1919.-

Patented Sept. ,21, 1920.

6 SHEETS'SHEE T 2.

INI/EIVTOR a -W ATTORNEY w. H. WOODWARD. ROTARY INTERNAL COMBUSTION ENGINE.

APPLICATION FILED FEB. 10. I919. Patentedseptl 21 6 SHEETS-SHEET 3.

INVENTOR A TTORNEY W. H. WOODWARD ROTARY INTERNAL COMBUSTION. ENGINE: APELICATION mp0 FEB.10. m's.

Patented Sept. 21, 1920.

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IN l/EN TOR mom/1 w. H. WOODWARD. ROTARY INTERNAL COMBUSTION ENGINE.

Patented Sept. 21,1920.

s SHEETS-SHEET 5 APPLICATION HLED FEB. I0, 1919.

. mymrm W. H. WOODWARD. ROTARY INTERNAL COMBUSTION ENGINE.

Patented Sept. 21,1920.

APPUCATION FILED FEB. 10. 1919. 1,353,205.

6 SHEETS-SHEET 6.

INVENTOR my; 74M

' A TTORIIEY WOODWAR'D, OF CLEVELAND, OHIO, ASSIGNOR- 0F TWO-FIFTHS TO LOUIS SWENINGSON AND ONE-FIFTH TO GEORGE M. POTTER, BOTH OF CLEVELAND, OHIO.

i ROTARY INTERNAL-COMBUSTION ENGINE.

Specification of Letters Patent.

Patented Sept. 21, 1920.

Application filed February 10, 1919. Serial No. 276,012.

To all whom it may concern:

Be it known that 1, WILLIAM H. WOOD- wARn, a citizen of the United States, resid- .ing at Cleveland, in the countyof Cuyahoga and State of Ohio, have invented certain new and useful- Improvements in Rotary Internal-Combustion. Engines, of .which the following is a specification.

This invention relates to improvements in rotary engines of the internal combustion type, and has for its object to provide an en gine of the above type which will be very powerful in proportion to its size and weight, and contain few moving. parts so arranged as to cheapen its construction while greatly adding to its efficiency.

A' further object of my invention is to provide an engine of the type specified, containing a minimum of moving parts which do no require adjustment, 'making it a desirable engine when in use in unskilled hands; and providing an engine that may be used. wherever engines of this type are required especially where space is limited or in air craft where light engines and high power'are essential.

A still further object of my invention is to provide an engine of the above type,

which operates on the four cycle principle without the use of valves, but so arranged as to cause its cylinder ports to pass over exhaust and inlet chambers respectively, which allows said cylinders or compartments to remain in communication with said exhaust and inlet chambers for a longer period in relation to their degree of travel than is usually found in internal combustion engines, insuring a more thorough'scavenging of cylinders, and will, by gradually opening after each charge has expanded, produce a quiet running engine. o I

' A still further object of my invention is .to produce an engine of the type specified,

plus the rotating actionof the engine also enables me to dispense with the use of a fly wheel. 4

A still further object of ,my invention is to produce an engine of the above type with novel means for cooling, and my invention further consists in certain other 'novel details of construction and in combinations of parts, all of which will be first fully described .and afterward specifically pointed out in the appended claims.

In the accompanying drawings a preferred embodiment of my invention is illustrated, but it will be understood that various changes and modifications may be made, as to the details of the construction and arrangement of the parts, without departing from thespirit of the invention;

Figure -1 is a longitudinal partial sectional view of the engine on line 11 of Fig. 5 and line 1-1 of Fig. 6. Fig. 2 is a crosssection of the engine on line 2-2 of Fig. 1 androtated to position shown in Fig. 8, showing the ignition system, and rear air case, in elevatlon.

Fig. 3 is an elevation of the back end of the engine, with parts of the air case broken away to better show the cylinder, and with a pocket on back cylinder head in section onthe line 33 of Fig. ,1, and exhaust and inlet chambers in sectionv on lines 4-41 and (S -6 of Fig. 1. i Fig. 4 is a section on line 4& of Fig. 1 showing pockets which connect the exhaust chamber with the cylinder compartments respectively.

.Fig. .5 is an end elevation of the crank case with the casing in section.

Fig. 6 is asimilar elevation of the crank case with the parts in different position.

Figs. 7, 8, 9 and 10 are diagrams showing the different positions of the piston and cylinder during the course of one revolution.

In constructing my engine I employ a substantial frame 1: on which are securely mounted two bearings. 2 and 2 which support a shaft 5 on which is mounted a wrist plate 16 and a two bladed piston 4;, the wrist plate and piston being keyed or otherwise rigidly fixed to the shaft. A cylinder 3, with opposite heads 6 and 7, is rotatably mounted on the shaft 5. Loosely mounted on the shaft 5 on the inner side of front bearing 2 is a stationary or abutment gear 12 which has a collar 43 extending through front bearing 2', and'serving as a front bearing for shaft 5, and being securely held against rotation in bearing 2' by a key 44:.

' The shaft 5 wrist'plate 16 and piston 4 are rigid and rotate as one member, and the crank case 11, front head 6, cylinder 3 and back head 7 are all rigid with one another and in operation rotate as another memberaround the shaft 5.

On the inner side of crank case 11,'extending toward the center, and forming partof said crank case 11, are two arms 18,

each supporting a stud shaft 18 having on one end a fixed pinion 13 meshing with the stationary gear 12, and having on its opposite end a crank 14 which is connected to wrist plate 16 by a link 15, thus causing said plate 16, shaft 5, and piston 4 to rotate intermittently while ear case 11, cylinder 3 and its heads 6 an 7 rotate continually forming a fly-wheel, as more fully described hereinafter.

Cylinder 3 is divided by partitions or abutments-S and piston hub 25 into two com-- partments which are intersected by the double winged piston 4 into two more com-- partments which are closed atthe ends by cylinder heads 6 and 7 and form four compartments A, B, C and D,'each of which,

owingto the pinions 13 being one half the size of the stationary or abutment gear 12, will fire at each revolution of the engine, that is, each compartment will take gas, compress it, fire it, use its expansion, and discharge once every revolution, which' with four compartments gives four impulses during each revolution.

Theback head 7 is provided with orts (see Fig. 2) 29 from compartment 30 from compartment B, 31 fromcompartment" G and 32 from compartment D, each one communicating with a separate pocket 20 which in turn pass over an exhaust passage 46 and an inlet passage 45 respectively.

Pockets 20 are provided with spring packsleeves 19 provided with packing rings Pockets 20 are cast on the inside of-a ring or band 47 and-the openings of said pockets form part of the face of said band 47, and as shown in Figs. 1 and 3 said pockets and ring are bridged away from the cylinder head 7 by ribs or blades 17. The ports or

passages

29, 30, 31 and 32 extend lengthwise from the cylinder head and connect pockets 20 and the respective cylinder compartments,

,at the same time allowing a current of air to be drawn over the outer face of the head 7 and the cylinder 3 by the blades 17 for the purpose of cooling the cylinder and associated parts.

Telescoped over the ring or band 47 as shown in Figs. 1 and 3 is a stationary band 48 which supports, on less than one half of its circumference, the exhaust passage 46 and the inlet passage 45. (See Fig. The upper half of band 48- is solid or closed,

while the lower half is open or slotted into,

thepassages 45 and 46, so that when the pockets 20 are revolving incontact with said band 48 they will hold compression and 'expansion while passing over the closed part, and exhaust and take gas while passing over the openings to said passages.

As shown in Fig. 1 the band 48 is a part of a casing or jacket 9 which extends around the head 7 and almost to the middle of cylinder 3, and forms an air casing, and is fastened immovably to the frame 1 by arms 49.

There is a similar case 10 over the opposite the same manner, and a circular space 24 is left as shown in Fig. 1 between the inner ends of case 9 and case 10, through which air that has been used for cooling purposes leaves the engine.

end of the cylinder, fastened toframe 1 in On the outer surfaces of heads 6 and 7 and cylinder 3, and-forming part of same, are radial ribs or blades 17, which, when the engine is rotating, serve as a blower, taking in .airat the head 6 through an opening 22,

and at head 7 through opening 28, and discharging said air at opening 24, for the purpose of cooling the engine.

Ignition is effected by spark plugs 33, 34, 35 and 36, in the respective compartments A, B, C and D, "said.plugs carrying

wiper contacts

37, 38,. 39 and 40 which wipe over a contact 41 mounted on the shell 10 and -which-may be shiftedtoadvance or retard will rotate the piston 4 o'ne-halfa revolu-. tion and cylinder 3 one-quarter revolution in clockwise direction, the cylinder forming the abutment for the impact. In the meantime the gas in compartment A will be compressed, the dead gases in compartment C will be exhausted and compartment B Wlll have a fresh charge to compress as shown in Fig. 8. At the nextignition, in compartment A, the piston will form the abutment and the impact will'take place against the the position shown in Fig. 6. Thatfis, it

cylinder partition, carrying the cylinder to the position shown 1n Fig: 9. -When the next explosion takes place, in compartment B, as

shown in Fig. 9, it will carry piston 4 around to position shown-in Fig. 10 after which the next explosion takes place in. compartment C and carries thecylinder aroundto the po- 1 sition shown in Fig. 7, and then the operationis repeated. i v

It has been made clear that cylinder 3,

iao

crank case 11 and pinions 13 rotatearound shaft 5 as one member with said pinionsin mesh with the stationary gear 12.

It has also: been made clearthat piston v shaft 5 and wrist plate 16 rotate as another member, and as shown in Figs. 1, 3 and 6, said plate,16,;a -nd cranks 14 of pin- 1011513, are connected by links 15.- It has i 'also been made clear that pinions 13 are one-half the size of stationary gear 12 so that for every revolution of. crank case 11 there will be two revolutions of pinions 13 or four strokes of links 15, each stroke consisting of one-half a revolutionjof pinions 13 and one quarter revolution of crank case 11, so that for each half a revolution of pinions 13 or for each-stroke of links 15, two

' compartments in the cylinder will be opened inlet and two will be closed. Regarding the. two compartments which open, one is taking gas while the other is expanding ignited gas,

and regarding the two compartments which close, one is compressing gas while the other is exhausting used or dead gas. The above operation embraces one-half a revolution of pinions 13, onestroke of link 15, and onequarter revolution of the enginepr'oper, and is repeated to complete a revolution.

It has been made clear that each compart ment opens and closes twice during one complete revolution of theengine, therefore as compartment A begins to openv as cylinder port 29 begins to communicate with assage 46, said compartment A. takes gas uring. one-quarter revolution of. 0311 inder 4' at the end of which time port-'29;

the other, and each of the aforesaid compartments is fired once each revolution;

It will be apparent that when an explosion takes place in compartment D as shown in Fig. -7, with the pinions 13 and wrist-plate 16 in position as shown in Fig. 5, with cranks 14 in their outer position,

piston 3 and .wrist plate 16 Will berotated clockwise one-half a revolution, rotating pinion gears one half a revolution, and cyL inder one quarter revolution, .bringlng cranks 14 to their inner position as shown in Fig. 6. On this stroke the cylinder partition 8 serves as an abutment for the explosion. The .force ofthe explosionisjust as great against said abutment 8 as 1t 15 'against piston 4 but'pi ston'4 offers no re-.

sista'nce and rotates away from abutment '8 at twice the speed of thecylinder thereby rotating pinions 13 around stationary gear 12 in a planetary course.

4 forms the abutment, and the impact rotates the cylinder, the operation is as fol lows: Assuming that an explosion takes place in compartment A with'the iston in position shown in-Fig. 8 and cran 's 14 on their inner position as shown in Fig. 6, it will be apparent that any pressure of the explosion tending to reverse the piston 4 'Will be prevented bythe fact that-the momentum of the engine has carried pinions 13 clockwise beyond dead center-and that it On the other stroke, or when the piston is impossible to further rotate said pinion gears '13 clockwise by aforesaid impact against piston 4 in compartment A because the stationary gear. 12 is immovable. In

other words if. cranks are on the outer posi tion and beyond dead center clockwise it is possible to rotate the engine one quarter revolution by turning wrist plate 16'clockto further rotate engine itis necessary to turn the cylinder, as the piston will requarter revolution of engine. The piston 4 is held against reversing by wrist plate 16 hearing against links 15 which in turn bear against cranks 14 which are rotated clock- "wise beyonddead center and which in turn are held by the teeth on pinions'13 meshingin the teeth of stationary gear 12v .which 2' by key 44.

in turn is held immovable front bearing.

It may be noted that pinions 13 have two positions to one of wrist plate 16, and in turning clockwise from a vertical position to a horizontal position do not materially afi'ect the position of piston 4, but will have carried the cylinder one quarter revolution.

It may also be noted that the piston in this engine does not oscillate, but rotates one half turn at twice the speed of the cylinder and thenwaits for the cylinderto, overtake it. In other words, 'on one stroke with the gears in posltion shown in Fig. 5

the impact or explosion will rotate the piston one half revolution, which being con nected to crank 14 by links 15 will rotate the cylinder one quarter revolution to position shown in Fig. ,6; at which time the pis: .ton forms an abutment by the gears being locked in mesh.

Iclaim:

1. In a rotary internal combustion en ine, the combination of a frame, a gear xed thereto, a rotary Cylinder in the frame, having'two opposite radial artitions therein, a rotary plston in the cy inder having two wings projecting oppositely between the partitions, and forming therewith four explosion chambers, awrist plate rigid with "wise one half a revolution, but it would be; impossible to reverse the piston, therefore main relatively stationary during the next A the piston, planetary pinions carried by the cylinder in mesh with said gear, said p1nions being half the diameter of the gear, a crank connected to the shaft of each pinion, and links connecting the wrist plate and the pinion cranks. V v

2. In a rotary internal. combustion engine, the combination of a rotary cylinder having explosion chambers therein, segmental inlet and exhaust passages adjacent one end of the cylinder, and pockets carried by the cylinder and communicating with said chambers and'arranged to travel over and communicate with said passages during the rotation of the cylinder;

3. In a rotary internal combustion engine, the combination of a rotary cylinder having explosion chambers therein, radial pockets carried by the cylinder and communicating at their inner ends with ports in the end of the cylinder leading to said chambers, and a ring in contact with the outer ends of said pockets, said ring having inlet and exhaust passages with which said pockets communicate during part of each revolution of the cylinder.

4c. In a rotary internal combustion engine, the combinationof a rotary cylinder having explosion chambers therein, radial pockets a ring in contact with the outer ends of said pockets, said ring having inlet and exhaust passages with which said pockets communicate during. part of each revolution of the cylinder.

5. In a rotary internal combustion engine,

the combination with a rotary cylinder, of

an air jacket around. the cylinder, having inlet openings at opposite ends of the cylinder and an outlet opening at the middle, the

ycylinder having ribs adapted to force air throu h said opening.

6. n a rotary internal combustion engine,

the combination with a rotary cylinder, of.

an air jacket comprising two cup-shaped sections over the ends of the cylinder, said sections having central inlet openings and being spaced apart at the middle to form an outlet opening extending around the cylinder, the cylinder having fan ribs thereon.

In testimony whereof, I do atlix my signature in presence of two witnesses.

WILLIAM II. WOODWARD. Witnesses:

JOHN A. BOMMHARDT, ROBERT L. BRUCE.